FR2773280A1 - SWITCHED MODE POWER SUPPLY - Google Patents

Abstract

The invention relates to a switching mode power supply (301) comprising a transformer (321), a power transistor (381), rectifiers (331, 332), filters (341, 342), a feedback part (351 ), a power transistor control part (361) and a synchronous signal control part (371). The transformer (321) includes an input winding (323) and a feedback winding (325); the power transistor (381) includes first and second electrodes; the rectifiers (331, 332) rectify the voltage generated by the secondary windings in direct current; the filters (341, 342) filter the DC voltage output from the rectifiers (331, 332) and output it as the output voltage; the feedback portion (351) returns a portion of the output voltage to the power transistor control portion (361); the power transistor control portion (361) controls the power transistor (381); the synchronous signal control part (371) activates the power transistor (381).

Description

SWITCHED MODE POWER SUPPLY

DESCRIPTION

BACKGROUND OF THE INVENTION

  Field of the Invention The present invention relates to a power supply and, more particularly, to a switching mode power supply intended to deliver direct current power.

Description of Related Art

  A power supply to deliver power is used in all systems using electricity. The power supply must provide stable power. If the power supplied by the power supply is unstable, the system receiving the power may malfunction. Therefore, the provision of stable power is an essential condition of the diet. In a switching mode supply, switching means are used

  in order to deliver stable power.

  Figure 1 is an embodiment of a power supply in conventional switching mode. With reference to FIG. 1, the power supply in conventional switching mode 101 comprises a power source 191, an input control part 111, a transformer 121, first and second diodes 131 and 132, first and second capacitors 141 and 142, first and second damping circuits 151 and 152, a feedback signal generating portion 161, a feedback signal receiving portion 171 and an integrated power switching circuit 181. The integrated circuit power switching 181 comprises a comparator 183, a control part 185, and a power transistor 187. The transformer 121 comprises an input winding 123 and a feedback winding 125 in the windings of the primary and of the first and second windings 127 and 128 in the

secondary.

  An input voltage Vi is applied to the input winding 123 of the transformer 121 through the input control part 111. When the power switch is closed, a current flows to the power transistor 187 through the input winding 123. When the power transistor 187 is turned off, a voltage is generated in the first and second windings 127 and 128 and in the feedback winding 125. Then the first and second diodes 131 and 132 are set to the on state. When the first and second diodes 131 and 122 are turned on, the voltage generated in the first and second windings 127 and 128 is rectified by the first and second diodes 131 and 132, filtered by the first and second capacitors 141 and 142 and output as the output voltage Vo of the power supply in switching mode 101. The output voltage Vo is returned to the feedback signal receiving portion 171 through the feedback signal generating portion 161. The feedback signal generating portion 161 converts the output voltage Vo to an optical signal and transmits it. The feedback signal receiving portion 171 receives the optical signal transmitted by the feedback signal generating portion 161, converts it into an electrical signal and transmits it to the

  integrated power switching circuit 181.

  The integrated power switching circuit 181 comprises a comparator 183, a control part 185 and a power transistor 187. An NMOS transistor is used as a power transistor 187. The signal transmitted from the reception part of the feedback signal 171 is transmitted to the transistor

  power 187 through the control part 185.

  When the output voltage Vo is greater than the voltage returned from the power transistor 187, the power transistor 187 is set to the off state. When the power transistor 187 is turned off, the output voltage decreases. When the output voltage Vo is lower than the voltage returned from the power transistor 187, the power transistor 187 is turned on and

the output voltage increases.

  A reference voltage Vr of 6.2 volts is applied to an inverting input (-) of the comparator 183. A synchronous voltage Vsync, in which a synchronous signal * sync applied from the outside is added to a control voltage Vp output of the control part 185, is applied to a non-inverting input. When the synchronous voltage Vsync is greater than the reference voltage Vr, the

  power transistor 187 is turned on.

  On the other hand, when the synchronous voltage Vsync is lower than the reference voltage Vr, the power transistor 187 is set to the off state. The waveform of the synchronous voltage Vsync is shown on the

figure 2.

  Figure 2 shows waveforms of signals applied to and output from the integrated power switching circuit 181 shown in Figure 1. Referring to Figure 2, when a feedback winding voltage Ve generated between the two ends of the feedback winding 125 is positive, the power transistor 187 is turned off. When the feedback winding voltage Ve is negative, the power transistor 187 is turned on. When the synchronous voltage Vsync is greater than the reference voltage Vr just after the power transistor 187 is turned off, a transient overvoltage 201 of approximately 500 volts is generated in the first and second diodes 131 and 132. When transient overvoltage 201 is generated, the first and second diodes 131 and 132 can be broken, thus losing

their righting function.

  The transient overvoltage 201 is generated as follows. When the level of the synchronous voltage Vsync exceeds that of the reference voltage Vr, the

  power transistor 187 is turned on.

  When the power transistor 187 is then turned on, a voltage is generated in the first and second windings 127 and 128. Consequently, the first and second diodes 131 and 132 become conductive. When the first and second diodes 131 and 132 are conductive, the current generated in the first and second windings 127 and 128 gradually decreases, flowing through the first and second diodes 131 and 132. When the power transistor 187 is switched on passing state and then put in the blocked state before the current flowing through the first and second diodes 131 and 132 decreases sufficiently, a voltage is generated in the first and second windings 127 and 128. Consequently, the transient overvoltage 201 is generated through the first and second diodes 131 and 132. The transient overvoltage 201 can seriously damage

  the first and second diodes 131 and 132.

  The power supply in conventional switching mode 101 uses the first and second damping circuits 151 and 152 in order to reduce the transient overvoltage 201. The first and second damping circuits 151 and 152 are connected, respectively, to the first and second diodes 131 and 132, in parallel. The first and second damping circuits 151 and 152 protect the first and second diodes 131 and 132 by absorbing the transient overvoltage 201 when the transient overvoltage 201 is generated through the first and

second diodes 131 and 132.

  The first damping circuit 151 comprises a diode 151a, a capacitor 151b and a resistor 151c. The first damping circuit 151 and the second damping circuit 152 have the same structure. The expense of manufacturing the switching mode power supply 101 increases because of the first and second damping circuits 151 and 152. To eliminate the need for the first and second damping circuits 151 and 152, the first and second diodes 131 and 132 can be replaced by diodes having a short reverse recovery time. However, diodes with a short reverse recovery time are expensive, so this option is not really less expensive if the generation of the transient overvoltage can be avoided, it is not necessary to use the first and second circuits d damping 151 and 152 and the diodes having a

  short reverse recovery time.

SUMMARY OF THE INVENTION

  To solve the above problem (s), an object of the present invention is to provide a switching mode power supply to avoid the

  generation of a transient overvoltage.

  To achieve the above object, the switching mode power supply according to the present invention comprises a transformer, a power transistor, rectifiers, filters, a feedback part, a power transistor control part and

  a synchronous signal control part.

  The transformer includes an input winding at one end of which an input voltage is applied and a feedback winding, one end of which is grounded, and to which energy is returned from a secondary winding, in a primary winding, and at least one winding

high school.

  The power transistor has a first electrode and a second electrode connected to each other

  end of the input winding and a ground.

  Rectifiers, whose input ports are connected to the other ends of the windings, rectify the voltage generated by the windings of the

secondary in direct current.

  The filters, connected between the rectifier outputs and ground, filter the DC voltage output from the rectifiers and output it as

output voltage.

  The feedback part, connected between the output of either the filters or of the power transistor control part, returns part of the output voltage to the transistor control part

power.

  The power transistor control part, the output port of which is connected to the power transistor control electrode, controls the power transistor in response to a signal output from the feedback part and to a synchronous signal

  applied from the outside.

  The synchronous signal control part, connected between the other end of the feedback winding and the power transistor control part, to which the synchronous signal is applied, puts the power transistor in the on state just before or just after switching on the power transistor after switching off the power transistor, in an initial step in which the synchronous signal begins to be applied in response to the voltage generated in

the feedback winding.

  According to the present invention, the output voltage is stable and the power supply in switching mode is less expensive.

BRIEF DESCRIPTION OF THE DRAWINGS

  The above objects and advantages of the present invention will become more apparent on reading the

  description of a preferred embodiment of

  the invention, given with reference to the accompanying drawings, in which: FIG. 1 is a diagram of an embodiment of a power supply in conventional switching mode; Figure 2 shows waveforms of signals applied to and output from an integrated power switching circuit shown in Figure 1; Figure 3 is an embodiment of a switching mode power supply according to the present invention; Figure 4 is an embodiment of an input control part shown in Figure 3; Figure 5 is an embodiment of a feedback portion shown in Figure 3; Figure 6 is a block diagram of a power transistor control portion shown in Figure 3; FIG. 7 is a diagram of an embodiment of a synchronous signal control part shown in FIG. 3; Figures 8a and 8b show waveforms of voltages in a discontinuous mode and in a continuous mode of the current flowing in the synchronous signal control part shown in Figure 7; Figure 9 is an embodiment of a power source shown in Figure 3; and Figure 10 shows waveforms of signals applied to the power transistor and the power transistor control portion shown on the

Figure 3 and out of it.

  DESCRIPTION OF THE PREFERRED EMBODIMENT

  Hereinafter, an embodiment according to the present invention will be described in detail, with reference to

attached drawings.

  Figure 3 is an embodiment of a power supply according to the present invention. Referring to Figure 3, a switching mode power supply 301 according to the present invention comprises a transformer 321, an input control part 311, a power transistor 381, first and second rectifiers 331 and 332, first and second filters 341 and 342, a feedback part 351, a power transistor control part 361, a power source 391 and a control part

synchronous signal 371.

  The transformer primary windings 321 include an input winding 323, at one end of which an input voltage Vi is applied, and a feedback winding 325 to which the energy

  is returned from the secondary windings.

  The transformer secondary windings 321 include first and second windings 327 and 328, one end of which is grounded. In the transformer 321, the energy is accumulated according to a spot return process in the input winding 323 when the power transistor 381 is turned on and the energy accumulated in the input winding 323 is transmitted to the first winding 327, to the second winding 328 and to the feedback winding 325 when the transistor

  of power 381 is put in the blocked state.

  In power transistor 381, a first electrode, i.e., a drain, and a second electrode, i.e., a source, are connected between the other end of the input winding. 323 and mass (GND). The power transistor 381 control electrode, i.e. a gate, is connected to the output of the power transistor control portion 361. The power transistor 381 is turned on when the signal voltage generated by the power transistor control portion 361 is high. Power transistor 381 is turned off when the signal voltage generated by the output of the control portion

  power transistor 361 is low.

  The input voltage Vi is applied to the input of the input control part 311 and the output port of the latter is connected to the input winding 323 of the transformer 321. The control part of input 311 protects the power transistor 381 by absorbing the transient overvoltage generated in the winding

  input 323 of transformer 321.

  The first rectifier 331 comprises a diode having an anode connected to the ungrounded end of the first winding 327 of the transformer 321 and a cathode connected to the positive terminal of the first filter 341. The first rectifier 331 rectifies the alternating current output from the first winding 327 of the transformer 321 into a direct current and

apply it to the first filter 341.

  The first filter 341 comprises an electrolytic capacitor having a positive terminal (+) connected to the output of the first rectifier 331 and a negative terminal (-) connected to the ground GND. The first filter 341 filters the DC voltage rectified by the first rectifier 331. The filtered DC voltage is output as the output voltage Vo of

  power supply in switching mode 301.

  The second rectifier 332 comprises a diode having an anode connected to the ungrounded end of the second winding 328 of the transformer 321 and a cathode connected to the positive terminal of the second filter 342. The second rectifier 332 rectifies the alternating current output of the second winding 328 of the transformer 321 into a direct current and applies it

to the second filter 342.

  The second filter 342 comprises a capacitor having a positive terminal (+) connected to the output of the second rectifier 332 and a negative terminal () connected to ground GND. The second filter 342 filters the DC voltage output from the second rectifier 332. The filtered DC voltage is output as the voltage of

  Vo output of the power supply in switching mode 301.

  The feedback part 351 is connected between the output of the second filter 342 and the power transistor control part 361. The feedback part 351 returns the output voltage Vo to the power transistor control part 361. The inputs of the power transistor control part 361 are connected to the output of the feedback part 351 and to the output of the synchronous signal control part 371. An output is connected to the control electrode of the power transistor 381. The power transistor control part 361 controls the power transistor 381 in response to a signal output from the feedback part 351, a synchronous sync signal applied from the outside and a synchronous control voltage Vt applied from the synchronous signal control portion 371. A synchronous voltage Vsync is generated by adding the synchronous signal

  sync at the synchronous control voltage Vt.

  The synchronous signal control part 371 is connected between the ungrounded end of the feedback winding 325 and the power transistor control part 361. The synchronous signal control part 371 puts the power transistor 381 in the on state just before or after the on state of the power transistor 381 after the on state of the power transistor 381, in an initial step in which the synchronous signal 4 sync begins to be applied in response to the feedback winding voltage Ve

  generated by the feedback winding 325.

  The power source 391 is connected between the feedback winding 325 and the power terminal of the power transistor control part 361. The power source 391 delivers a supply voltage Vcc to the control part of power transistor 361 in response to voltage

of feedback winding Ve.

  Figure 4 is an embodiment of an input control part 311 shown in Figure 3. With reference to Figure 4, the input control part 311 comprises a resistor 401, a capacitor 403 and a diode 405. One end of the resistor 401 and one end of the capacitor 403 are connected to one end N1 of the input winding 323. In the diode 405, the cathode is connected in common to the other ends of the resistor 401 and of the capacitor 403 and the anode is connected to the other end N2 of the input winding 323. The input voltage Vi is applied to one end of the resistor 401 and of the capacitor 403. The input control part 311 is a damping circuit. The input control part 311 protects the power transistor 381 by absorbing the transient overvoltage generated by the winding

  input 323 of transformer 321.

  FIG. 5 is an embodiment diagram of a feedback part 351 shown in FIG. 3. With reference to FIG. 5, the feedback part 351 comprises a feedback control part 501 and

an optocoupler 503.

  Optocoupler 503 is connected to the output port

  of the feedback control part 501.

  The optocoupler 503 includes a photodiode 551 for converting an electrical signal to an optical signal and a phototransistor 553 for converting an optical signal to an electrical signal. The electrical signal generated from phototransistor 553 is transmitted to the part

  power transistor 361.

  The feedback control part 501 transmits part of the output voltage Vo to the optocoupler 503 without loss. The feedback control part 501 includes first to fourth resistors 511, 512, 513 and 514, a capacitor 521 and a precision voltage reference 541. The capacitor 521 improves the charge regulation of the output voltage Vo by increasing sufficiently low frequency loop gain. The resistor 512 intended to apply a bias to the precision voltage reference 541 can make the flow of current through the

photodiode 551 almost zero.

  FIG. 6 is a block diagram of a power transistor control part 361 shown in FIG. 3. With reference to FIG. 6, the power transistor control part 361 comprises first and second comparators 601 and 602, an oscillator 611, an additional power source 641, a flip-flop 621 and a

control part 631.

  In the additional power source 641, an input is connected to the feedback portion 351 and an output is connected to the first and second comparators 601 and 602. The additional power source 641 delivers a predetermined voltage, for example, 5 volts, to the first comparator 601 and controls the second comparator 602 in response to the output signal from the feedback portion 351. The additional power source 641 includes first and second current sources 651 and 652, first to third diodes 661 , 662 and 663, first to third resistors 671, 672 and 673 and a

capacitor 681.

  One end of capacitor 681 is connected to GND ground. The other end of the capacitor 681 is connected to the output of the first current source 651. The capacitor 681 filters the noise included in

  the output signal from the feedback part 351.

  The cathode of the first diode 661 is connected to the output of the first current source 651. The anode of the first diode 661 is connected to the output of the second current source 652. When the voltage applied to the anode of the first diode 661 is greater than the voltage obtained by adding the voltage drop of the first diode 661 to the voltage applied to the cathode of the first diode 661, the first diode 661 is set to the on state. Consequently, the current flows from the anode of the first diode 661

  to the cathode of the first diode 661.

  The anode and the cathode of the second diode 652 are, respectively, connected between the output of the

  second current source 652 and the non-input

  inverting (+) of the first comparator 601. One end of the first resistor 671 is connected to the cathode of the second diode 652. A supply voltage Vcc is applied to the other end of the first resistor 671. A predetermined voltage is applied to the non-inverting input (+) of the first

  comparator 601 through the first resistor 671.

  The anode of the third diode 663 is connected to the output of the second current source 652. One end of the second resistor 672 is connected to the cathode of the third diode 663. The third resistor 673 is connected between the other end of the second resistor 672 and the GND ground. The other end of the second resistor 672 is connected to

  the non-inverting input (+) of the second comparator 602.

  When the voltage applied to the anode of the first diode 661 is less than the voltage obtained by adding the voltage drop of the first diode 661 to the voltage applied to the cathode of the first diode

  661, the third diode 663 is put on.

  Therefore, the voltage is applied to the second resistor 672 and the third resistor 673. The voltage is divided by the second resistor 672 and the

  third resistor 673 and applied to the non-input

  inverting (+) of the second comparator 602.

  The synchronous voltage Vsync and the voltage generated by the additional power source 641 are applied to the non-inverting input (+) of the first comparator 601. A predetermined reference voltage Vr, for example, 6.2 V, is applied to the inverting input (-) of the first comparator 601. The first comparator 601 compares the voltage applied to the non-inverting input (+) with the voltage applied to the inverting input (-) and generates an output signal in accordance with the result. Namely, when the voltage applied to the non-inverting input (+) of the first comparator 601 is greater than the voltage applied to the inverting input (-) of the first comparator 601, the first comparator 601 generates a level signal

  high. When the voltage applied to the non-input

  inverting (+) of the first comparator 601 is less than the voltage applied to the inverting (-) input of the first comparator 601, the first comparator

  601 generates a low level signal.

  The input of oscillator 611 is connected to the output of the first comparator 601. Oscillator 611 oscillates at a basic frequency, that is to say, 20 kHz, when the synchronous voltage Vsync is not applied. When the signal output from the first comparator 611 is high, the voltage of the output of oscillator 611 increases, positioning

thus the flip-flop 621.

  The power source output signal

  additional 641 is applied to the non-input

  inverting (+) of the second comparator 602. A predetermined voltage is applied to the inverting (-) input of the second comparator 602. A third current source 691 and a fourth resistor 693 are used to apply a predetermined voltage to the inverting input (-) of the second comparator 602. The supply voltage Vcc is applied to the input of the third current source 691. The fourth resistor 693 is connected between the output of the third current source 691 and the GND ground . The second electrode of the power transistor 381 is connected to a node N5 to which the fourth resistor 693 and the third current source 691 are connected. The current output from the third current source 691 and the current returned from the power transistor 381 flow in the fourth resistor 693. The voltage generated in the fourth resistor 693 is applied to the inverting input (-) of the second comparator 602 The second comparator 602 compares the voltage applied to the non-inverting input (+) with the voltage applied to the inverting input (-)

  and generates an output signal according to the result.

  Namely, when the voltage applied to the non-input

  inverting (+) of the second comparator is greater than the voltage applied to the inverting (-) input of the second comparator 602, the second comparator 602 generates a high level signal. When the voltage applied to the non-inverting input (+) is lower than the voltage applied to the inverting input (-), the

  second comparator 602 generates a low level signal. In other words, when the output voltage Vo is greater than the voltage

  returned from the power transistor 381, the second comparator 602 outputs a high level signal. When the output voltage Vo is lower than the voltage returned from the power transistor 381, the second comparator 602

outputs a low level signal.

  The setting terminal at one (S) of the flip-flop 621 is connected to the output of the oscillator 611. The reset terminal (R) of the flip-flop 621 is connected to the output of the second comparator 602. The flip-flop 621 is an RS flip-flop. The output of the RS flip-flop is shown on

table 1.

TABLE 1

  Input Output Reset Reset to (S) Q (R) 0 0 Maintain a previous state

O0 1 1

1 0 0

1 1 O

  As shown in table 1, when the signal voltages applied to the set terminal to one (S) and to the reset terminal (R) of the flip-flop RS are at the high logic level and at the low logic level respectively , a signal at an output terminal (Q) is activated at the high logic level. When the signal voltages applied to the set terminal to one (S) and to the reset terminal (R) are respectively at the low logic level and at the high logic level, the signal at the output terminal (Q) is disabled at low logic level. When the voltages of the signals applied to the setting terminal to one (S) and to the reset terminal (R) of the flip-flop RS are both at low logic level, the signal at the output terminal (Q) maintains a previous state. When the signal voltages applied to the reset terminal (S) and the reset terminal (R) are both at the high logic level, the output terminal voltage (Q) goes to the low logic level. The inversion of the signal output by the output terminal (Q) is output by the output terminal (Q) of the flip-flop RS. Namely, when the signal at the output terminal (Q) is at low logic level, the signal at the

  output terminal (Q) is at high logic level.

  When the output of the oscillator 611 is at the high level, the flip-flop 621 is positioned and

  the output terminal (Q) outputs a low level signal.

  When the output of the second comparator 602 is at the high level, the flip-flop 621 maintains a previous state. When the output of the oscillator 611 and that of the second comparator 602 are at the high level, the

  output of the flip-flop 621 is at the high level.

  In the control part 631, the input is connected to the output of the flip-flop 621 and the output is connected to the control electrode of the power transistor 381. The control part 631 largely sets the power transistor 381 to the state passing by amplifying the output signal of the flip-flop 621 when it is weak and by applying it to

  the power transistor control electrode 381.

  The power transistor control portion 361 and the power transistor 381 can be realized in an integrated circuit, such as the KA2S0680 and KA2S0880 manufactured by Samsung Electronics Co. Ltd. FIG. 7 is a diagram of an embodiment of a synchronous signal control part 371 shown in FIG. 3. With reference to FIG. 7, the synchronous signal control part 371 comprises a resistor 701 and first and second capacitors 703 and 705. One end of the resistor 701 is connected to the ungrounded end of the feedback winding 325. The positive terminal (+) and the negative terminal (-) of a first capacitor 703 (such as an electrolytic capacitor) are connected between the other end of the resistor 701 and the GND ground. The synchronous control voltage Vt is generated across the first capacitor 703. One end of the second capacitor 705 is connected to the other end of the resistor 701. The other end of the second capacitor 705 is connected to the transistor control part of power 361. The second capacitor 705 is a high-pass filter, which blocks a DC element included in the synchronous voltage Vt and allows only an AC element to pass. The synchronous control voltage Vt is applied to the power transistor control part 361 with the synchronous sync signal. The feedback winding voltage Ve charges the first capacitor 703 through the resistor 701. The synchronous control voltage Vt is generated at the point where the resistor 701 is connected to the first and second capacitors 703 and 705. The control voltage

  synchronous Vt is obtained by the following equation 1.

  Equation 1: Vt = Ve + (Vo-Ve) and / RC in which Vo is an initial voltage of the voltage

Vt synchronous control unit.

  As shown in Equation 1, the synchronous control voltage Vt is determined by the time constant of the resistor 701 and the first capacitor 703. It is therefore possible to control the slope of the synchronous control voltage Vt by controlling the constant resistance 701 time

and the first capacitor 703.

  Figures 8a and 8b show waveforms of voltages in a discontinuous mode and in a continuous mode of the current flowing in the synchronous signal control portion 371 shown in Figure 7. Referring to Figure 8a, then that the synchronous control voltage Vt gradually increases when the feedback winding voltage Ve is positive and that the synchronous control voltage Vt maintains a maximum value when the feedback winding voltage (Ve) is zero, in a discontinuous mode , the synchronous control voltage Vt gradually decreases when the voltage

  feedback winding (Ve) is negative.

  Referring to Figure 8b, in the continuous mode, the synchronous control voltage Vt gradually increases when the feedback winding voltage Ve is positive and the synchronous control voltage Vt gradually decreases when the voltage

  of the Ve feedback winding is negative.

  The synchronous signal * sync is applied to the non-inverting input (+) of the first comparator 601 of the power transistor control part 361,

  combined with synchronous control voltage V (t).

  Since a voltage of 5 volts is applied from the additional power source 641 to the non-inverting input (+) of the first comparator 601, the synchronous signal sync with V (t) is added to 5 volts and applied to the non-inverting (+) input of the first comparator 601. The second capacitor 705 of the synchronous signal control part 371 filters the DC element included in the synchronous control voltage Vt. Namely, the second capacitor 705 removes the subharmonic included in the voltage

Vt synchronous control unit.

  Figure 9 is an embodiment of a power source 391 shown in Figure 3. With reference to Figure 9, the power source 391 includes a resistor 901, a diode 903 and a capacitor 905. One end of resistor 901 is connected to the ungrounded end of feedback winding 325 and transmits feedback winding voltage Ve to diode 903. In diode 903, the anode is connected to the other end of the resistor 901 and the cathode is connected to the power transistor control part 361. The feedback winding voltage (Ve) is rectified into a DC voltage by the diode 903. The DC voltage rectified is filtered by the capacitor 905 and is used as the supply voltage (Vcc) of the power transistor control part 361. The capacitor 905 is an electrolytic capacitor having a positive (+) terminal connected to the cathode of diode 903 and a terminal

  negative (-) connected to ground (GND).

  Figure 10 shows waveforms of signals applied to the power transistor 381 and the power transistor control portion 361 shown in and out of Figure 3. Referring to Figure 10, when the feedback winding voltage (Ve) of the transformer 321 is positive in the continuous mode, the power transistor 381 is turned off. When the feedback winding voltage (Ve) of transformer 321 is negative, the power switch is closed. The synchronous 4 sync signal reaches 6.2 volts when combined with the synchronous control voltage Vt when

  the synchronous control voltage Vt is at a maximum.

  The synchronous signal does not reach 6.2 volts when combined with the synchronous control voltage Vt when the synchronous control voltage Vt is not at a maximum. The transient overvoltage is not generated by the synchronous voltage Vsync reaching 6.2 volts just after or just before the on state of the

power transistor 381.

  The operation of the power supply in switching mode 301 shown in FIG. 3 will be described

with reference to figure 10.

  When the input voltage (Vi) is applied to the input winding 323 in a state in which the power transistor 381 is turned on,

  energy is stored in transformer 321.

  When the power transistor 381 is turned off, a voltage is generated in the first and second windings 327 and 328 and in the feedback winding 325. The voltage generated in the feedback winding 325 is accumulated in the first capacitor 703 through the resistor 701 of the synchronous signal control part 371. The synchronous control voltage Vt has a uniform slope in accordance with the time constant of the resistor 701 of the synchronous signal control part 371 and the first capacitor 703. The synchronous control voltage Vt is applied to the non-inverting input (+) of the first comparator 601 of the power transistor control part 361. The synchronous signal 4 sync is applied from the outside to the non-inverting input (+) of the first comparator 601 of the power transistor control part 361. Namely, a signal in which the synchronous signal 4 sync is com hinned with the synchronous control voltage Vt is applied to the non-inverting input (+) of the first comparator 601 of the power transistor control part 361, as shown in FIG. 4. Also, the voltage of 5 volts is applied from the additional power source 391 of the power transistor control part 361 to the non-inverting (+) input of the first comparator 601 of the power transistor control part 361. So a voltage synchronous Vsync, in which the voltage of 5 volts, the synchronous control voltage Vt and the synchronous signal 4 sync are added to each other, is applied to the non-inverting input (+) of the first comparator 601 of the part of power transistor control 361. When the voltage obtained by adding 5 volts to the synchronous control voltage Vt is called control voltage Vc, the peak value of the control voltage Vc does not exceed 6.2 volts. When the synchronous signal 4 sync is combined with the control voltage Vc when the control voltage Vc does not have a peak value, the

  synchronous voltage Vsync applied to the input non

  inverting (+) of the first comparator 601 of the power transistor control part 361 does not reach 6.2 volts. The synchronous voltage Vsync reaches 6.2 volts only when the synchronous signal 4 sync is combined with the control voltage Vc when the

  control voltage Vc has a peak value.

  When the synchronous voltage Vsync reaches 6.2 volts, the first comparator 601 of the power transistor control part 361 outputs a high level signal. Therefore, the flip-flop 621 of the power transistor control portion 361 is positioned. When the flip-flop 621 of the power transistor control part 361 is positioned, the power transistor 381 is turned on.

the passing state.

  The control voltage Vc has a peak value just before or just after setting the power transistor 381 to the on state after having been set to the off state. Since the current flowing in the first and second rectifiers 331 and 332 is sufficiently reduced just before or just after the power transistor 381 is put into the on state, the transient overvoltage is not generated in the first and second diodes 331 and 332, even if the power transistor 381 is turned on

by the synchronous voltage Vsync.

  The transient overvoltage is not generated in the first and second rectifiers 331 and 332 since the synchronous voltage Vt reaches the voltage applied to the inverting input (-) of the power transistor control part 361 just before or just after putting the power transistor 381 into the on state after having been put into the off state. Therefore, the first and second rectifiers 331 and 332 are securely protected. Conventional damping circuits are not necessary since the transient overvoltage is not generated in the first and second rectifiers 331 and 332. The synchronous signal control part 371 has a simple structure. Manufacturing the power supply in switching mode 301 is therefore not expensive. As mentioned above, according to the present invention, it is not necessary to use the damping circuits since the generation of the transient overvoltage is avoided by using the synchronous signal control part 371. Therefore, manufacturing expenses of

  the supply in switching mode 301 are reduced.

  The present invention is not limited to the above embodiment; it is readily understood that many variations can be made by those skilled in the art without changing the scope and spirit of

the present invention.

Claims (15)

  1. Power supply in switching mode, characterized in that it comprises: a transformer (321) comprising an input winding (323) at one end of which an input voltage is applied and a feedback winding (325), one end of which is grounded, and to which energy is returned from a secondary winding, into a primary winding, and at least one secondary winding; a power transistor (381) comprising a first electrode and a second electrode connected between the other end of the input winding (323) and a ground; rectifiers (331, 332) whose input ports are connected to the other ends of the windings, for rectifying the voltage generated by the secondary windings in direct current; filters (341, 342) connected between the outputs of the rectifiers (331, 332) and ground to filter the direct voltage output from the rectifiers (331, 332) and to output it as an output voltage; a feedback part (351) connected between the output of either filters (341, 342) or of the power transistor control part (361), for returning part of the output voltage to the transistor control part power (361); a power transistor control portion (361), the output port of which is connected to the power transistor control electrode (381), for controlling the power transistor (381) in response to a signal output from the feedback part (351) and to a synchronous signal applied from the outside; and a synchronous signal control part (371) connected between the other end of the feedback winding (325) and the power transistor control part (361), to which the synchronous signal is applied to activate the transistor power (381) just before or just after the power transistor (381) has been switched on after the power transistor (381) has been switched off, in an initial stage in which the synchronous signal begins to be applied in response to the voltage generated in the feedback winding (325).   2. Power supply in switching mode according to claim 1, characterized in that the rectifiers (331, 332) are diodes in which the respective anodes are connected to the other ends of the secondary windings and the respective cathodes   are connected to the filters (341, 342).   3. Power supply in switching mode according to claim 1, characterized in that the filters (341, 342) are electrolytic capacitors in which the positive terminals are connected to the outputs of the rectifiers (331, 332) and the terminals   negative are connected to ground.   4. Switching mode power supply according to claim 1, characterized in that the feedback part (351) comprises: a feedback control part (501) having an input port connected to the output port of one of the filters (341, 342), to improve the characteristic of the output voltage; and an optocoupler (503) connected between the feedback control portion (501) and the power transistor control portion (361), for receiving and transmitting an electrical signal from the feedback control portion (501) at the party of   power transistor control (361).   5. Switching mode power supply according to claim 1, characterized in that the power transistor control part (361) comprises: an additional power source (641) for responding to a signal generated from the part of feedback (351); a first comparator (601) for comparing the voltage applied to a non-inverting input with the voltage applied to an inverting input, when a predetermined voltage generated by the additional power source (641) and a synchronous control voltage generated by the signal control part   synchronous (371) are applied to the non-input   inverting and that a predetermined reference voltage is applied to the inverting input, and for generating a high level signal when the voltage applied to the non-inverting input is greater than the voltage applied to the inverting input; an oscillator (611), the input of which is connected to the output of the first comparator (601), for generating a pulse signal in response to the output of the first comparator (601); a second comparator (602) for comparing the voltage applied to a non-inverting input with the voltage applied to an inverting input, when the voltage supplied from the power source   additional (641) is applied to the non-input   inverting and the voltage returned from the power transistor (381) is applied to the inverting input, and to generate a high level signal when the voltage applied to the non-inverting input is greater than the voltage applied to l 'inverting input; and a flip-flop (621), whose setting terminal is connected to the output of the oscillator (611), whose reset terminal is connected to the output of the second comparator (602) and whose output is connected to the power transistor control electrode (381), to activate the power transistor (381) when the output of the oscillator (611) is high and to deactivate the power transistor (381) when the output of   second comparator (602) is at the high level.   6. Power supply in switching mode according to claim 5, characterized in that the rocker   bistable (621) is an RS flip-flop.   7. Power supply in switching mode according to claim 1, characterized in that the synchronous signal control part (371) comprises: a resistor (701), one end of which is connected to the other end of the feedback winding (325) and the other end is connected to the input of the power transistor control part (361), to which the synchronous signal is applied; and a capacitor connected between the other end of the resistance and mass.   8. Power supply in switching mode according to claim 7, characterized in that the capacitor is an electrolytic capacitor, the positive terminal of which is connected to the other end of the resistor and the negative terminal of which is connected to ground. 9. Switching mode power supply according to claim 1, characterized in that the power transistor (381) and the power transistor control part (361) are produced in a integrated circuit.   10. Power supply in switching mode according to claim 1, characterized in that it further comprises a power source (391) connected between the power transistor control part (361) and the other end of the feedback winding (325), for supplying a supply voltage to the transistor control part power (361).   11. Switching mode power supply according to claim 10, characterized in that the power source (391) comprises: a resistor (901), one end of which is connected to the other end of the feedback winding (325);   a diode (903), the anode of which is connected to the other end of the resistor; and an electrolytic capacitor (905), the anode of which is connected to the cathode of the diode and the cathode of which is connected to ground.   12. Power supply in switching mode according to claim 1, characterized in that the part of   input control (311) is a damping circuit.   13. Power supply in switching mode according to claim 12, characterized in that the damping circuit comprises: a resistor, one end of which is connected to the other end of the feedback winding (325);   a diode, the anode of which is connected to the other end of the resistor; and an electrolytic capacitor, the anode of which is connected in common to the cathode of the diode and to the input of the power transistor control part (361), and the cathode of which is connected to ground. 14. Power supply in switching mode according to claim 1, characterized in that it further comprises a high-pass filter for removing a DC element from a signal output of the synchronous signal control part ( 371), between the input of the power transistor control part (361) to which the synchronous signal is applied and the   synchronous signal control part (371).   15. Power supply in switching mode according to claim 14, characterized in that the filter high pass is a capacitor.